Accurate grading of gastrointestinal stromal tumors (GISTs), based on mitotic index, can be problematic.In this study, we compared interobserver variability in detecting mitosis on H&E with PHH3 immunohistochemistry (IHC). In addition, we examined the correlation between H&E mitosis and Ki-67 and the association of PHH3 and Ki-67 with overall survival. Four pathologists independently reviewed 50 GIST cases.Intraclass correlation coefficients showed good interobserver variability for mitotic counts on both H&E (0.918; 95% confidence interval [CI], 0.874-0.950) and PHH3 IHC (0.923; 95% CI, 0.882-0.953). Nineteen (38%) cases were graded higher and five (10%) cases were downgraded by at least one observer using PHH3 compared with H&E. Using receiver operating characteristic curve analysis, a PHH3 cutoff of seven or more mitoses was associated with worse overall survival (P = .028). Ki-67 showed poor correlation with H&E mitotic counts and overall survival (P = .077).PHH3 may thus be a valuable adjunct for risk stratification in GISTs.

Non-tuberculous mycobacterioses comprise a group of diseases caused by mycobacteria which do not belong to the Mycobacterium (M.) tuberculosis-complex and are not ascribed to M. leprae. These mycobacteria are characterized by a broad variety as to environmental distribution and adaptation. Some of the species may cause specific diseases, especially in patients with underlying immunosuppressive diseases, chronic pulmonary diseases or genetic predisposition, respectively. Worldwide, a rising prevalence and significance of non-tuberculous mycobacterioses is recognized. The present recommendations summarise current aspects of epidemiology, pathogenesis, clinical aspects, diagnostics - especially microbiological methods including susceptibility testing -, and specific treatment for the most relevant species. Diagnosis and treatment of non-tuberculous mycobacterioses during childhood and in HIV-infected individuals are described in separate chapters.

Iron is one of the most important nonorganic substances that make life possible. Iron plays major roles in oxygen transport (eg, hemoglobin; ∼67% of total body iron [TBI]), short-term oxygen storage (eg, myoglobin; ∼3.5% of TBI), and energy generation (eg, cytochromes; ∼3% of TBI).1 Iron also serves vital roles in various nonheme-containing enzymes (∼2% of TBI). Figure 1 lists heme-containing and nonheme iron-containing proteins. TBI is controlled by the rate of iron absorption; there are no physiologic mechanisms to excrete excess iron. Iron deficiency has many adverse consequences, including anemia, and in children, behavioral and learning disorders.2-4 Iron excess is toxic to the body, harming the heart, liver, skin, pancreatic islet beta cells, bones, joints, and pituitary gland. Maintaining proper iron balance is essential for maintaining homeostasis and health. TBI in adults normally ranges between 3.5 and 5.0 g.5 A total of 75% of TBI is functional, and 25% is stored within cells as ferritin or hemosiderin. Ferritin contains 24 subunits of light chains (L chains; 19.7 kDa) and heavy chains (H chains; 21.1 kDa). The L chains are encoded on chromosome 19q13.33 and are 175 amino acids long. The H chains are encoded on chromosome 11q1 and are 183 amino acids long. Each ferritin molecule can contain as many as approximately 4500 ferric ions. Because the major role of iron is in hemoglobin synthesis, this review will focus on iron, iron transport, and hematopoiesis.